Susan B. Masters

Bio: Susan B. Masters is an academic researcher from University of California, San Francisco. The author has contributed to research in topics: G protein & Adenylyl cyclase. The author has an hindex of 11, co-authored 16 publications receiving 2551 citations.

GTPase inhibiting mutations activate the α chain of G s and stimulate adenylyl cyclase in human pituitary tumours

Abstract: A subset of growth hormone-secreting human pituitary tumours carries somatic mutations that inhibit GTPase activity of a G protein alpha chain, alpha(s) The resulting activation of adenylyl cyclase bypasses the cells' normal requirement for trophic hormone Amino acids substituted in the putative gsp oncogene identify a domain of G protein alpha-chains required for intrinsic ability to hydrolyse GTP This domain may serve as a built-in counter-part of the separate GTPase-activating proteins required for GTP hydrolysis by small GTP-binding proteins such as p21ras

Identification of receptor contact site involved in receptor-G protein coupling.

Abstract: The mammalian G proteins transduce information from extracellular signals, including neurotransmitters, hormones and sensory stimuli, into regulation of effector enzymes or ion channels within cells. Triggered by appropriate extracellular signals, receptor proteins specifically activate members of the G protein family by catalysing replacement of GDP by GTP at the guanine nucleotide binding site. Like the receptor proteins1, the heterotrimeric G proteins exhibit impressive structural similarities2,3, suggesting that all receptor–G protein interactions use homologous structural elements and a single molecular mechanism. Topologically equivalent portions of each G protein may therefore interact with the appropriate receptor. We recently predicted the secondary structure of a composite G protein α-chain and proposed that a predicted amphipathic α-helix at the extreme carboxy-terminus of the polypeptide directly contacts receptors4. This proposal has now been confirmed by sequencing complementary DNAs of the gene that encodes the α-chain (αs) of the stimulatory regulator (Gs) of adenylyl cyclase in wild-type cells and in a mutant mouse S49 lymphoma cell line, unc, in which Gs cannot be activated by hormone receptors5. The sequences reveal a point mutation in the unc gene that substitutes a proline residue for an arginine near the carboxy-terminus of the αs-polypeptide. Expression of recombinant αs-unc in genetically αs-deficient S49 cells reproduces the unc phenotype.

Family of G protein α chains: amphipathic analysis and predicted structure of functional domains

Abstract: The G proteins transduce hormonal and other signals into regulation of enzymes such as adenylyl cyclase and retinal cGMP phosphodiesterase. Each G protein contains an alpha subunit that binds and hydrolyzes guanine nucleotides and interacts with beta gamma subunits and specific receptor and effector proteins. Amphipathic and secondary structure analysis of the primary sequences of five different alpha chains (bovine alpha s, alpha t1 and alpha t2, mouse alpha i, and rat alpha o) predicted the secondary structure of a composite alpha chain (alpha avg). The alpha chains contain four short regions of sequence homologous to regions in the GDP binding domain of bacterial elongation factor Tu (EF-Tu). Similarities between the predicted secondary structures of these regions in alpha avg and the known secondary structure of EF-Tu allowed us to construct a three-dimensional model of the GDP binding domain of alpha avg. Identification of the GDP binding domain of alpha avg defined three additional domains in the composite polypeptide. The first includes the amino terminal 41 residues of alpha avg, with a predicted amphipathic alpha helical structure; this domain may control binding of the alpha chains to the beta gamma complex. The second domain, containing predicted beta strands and alpha helices, several of which are strongly amphipathic, probably contains sequences responsible for interaction of alpha chains with effector enzymes. The predicted structure of the third domain, containing the carboxy terminal 100 amino acids, is predominantly beta sheet with an amphipathic alpha helix at the carboxy terminus. We propose that this domain is responsible for receptor binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Carboxyl terminal domain of Gs alpha specifies coupling of receptors to stimulation of adenylyl cyclase.

Abstract: The alpha subunits of Gs and Gi link different sets of hormone receptors to stimulation and inhibition, respectively, of adenylyl cyclase. A chimeric alpha i/alpha s cDNA was constructed that encodes a polypeptide composed of the amino terminal 60% of an alpha i chain and the carboxyl terminal 40% of alpha s. The cDNA was introduced via a retroviral vector into S49 cyc- cells, which lack endogenous alpha s. Although less than half of the hybrid alpha chain is derived from alpha s, its ability to mediate beta-adrenoceptor stimulation of adenylyl cyclase matched that of the normal alpha s polypeptide expressed from the same retroviral vector in cyc- cells. This result indicates that carboxyl terminal amino acid sequences of alpha s contain the structural features that are required for specificity of interactions with the effector enzyme, adenylyl cyclase, as well as with the hormone receptor.

The GTPase superfamily: conserved structure and molecular mechanism

Abstract: GTPases are conserved molecular switches, built according to a common structural design. Rapidly accruing knowledge of individual GTPases--crystal structures, biochemical properties, or results of molecular genetic experiments--support and generate hypotheses relating structure to function in other members of the diverse family of GTPases.

Consensus coding sequences of human breast and colorectal cancers

Abstract: Analysis of 13,023 genes in 11 breast and 11 colorectal cancers revealed that individual tumors accumulate an average of ˜90 mutant genes but that only a subset of these contribute to the neoplastic process. Using stringent criteria to delineate this subset, we identified 189 genes (average of 11 per tumor) that were mutated at significant frequency. The vast majority of these genes were not known to be genetically altered in tumors and are predicted to affect a wide range of cellular functions, including transcription, adhesion, and invasion. These data define the genetic landscape of two human cancer types, provide new targets for diagnostic and therapeutic intervention and monitoring.

Identification of FAP locus genes from chromosome 5q21

Abstract: Recent studies suggest that one or more genes on chromosome 5q21 are important for the development of colorectal cancers, particularly those associated with familial adenomatous polyposis (FAP). To facilitate the identification of genes from this locus, a portion of the region that is tightly linked to FAP was cloned. Six contiguous stretches of sequence (contigs) containing approximately 5.5 Mb of DNA were isolated. Subclones from these contigs were used to identify and position six genes, all of which were expressed in normal colonic mucosa. Two of these genes (APC and MCC) are likely to contribute to colorectal tumorigenesis. The MCC gene had previously been identified by virtue of its mutation in human colorectal tumors. The APC gene was identified in a contig initiated from the MCC gene and was found to encode an unusually large protein. These two closely spaced genes encode proteins predicted to contain coiled-coil regions. Both genes were also expressed in a wide variety of tissues. Further studies of MCC and APC and their potential interaction should prove useful for understanding colorectal neoplasia.

The GTPase superfamily: a conserved switch for diverse cell functions

Abstract: Proteins that bind and hydrolyse GTP are being discovered at a rapidly increasing rate. Each of these many GTPases acts as a molecular switch whose 'on' and 'off' states are triggered by binding and hydrolysis of GTP. Conserved structure and mechanism in myriad versions of the switch--in bacteria, yeast, flies and vertebrates--suggest that all derive from a single primordial protein, repeatedly modified in the course of evolution to perform a dazzling variety of functions.